TECHNICAL FIELD
This invention relates generally to turbo-machinery, and in particular to a multi-stage supercharger arrangement with cross flow between compression stages.
BACKGROUND
Emissions regulations and market forces have continually driven engine manufacturers toward higher engine output, smaller overall size, and cleaner operation. Currently designers of state of the art internal combustion engines concentrate on the few tools still available to meet these challenges. A current area of focus for engine designers is the engine air system, and, more particularly, the combustion engine's turbomachinery or turbochargers.
State of the art combustion systems require the engine's air and fuel to be delivered to the combustion chamber at increasingly higher pressure and higher mass flow. With the desire to provide higher combustion air pressure (i.e., “boost” pressure), engine manufacturers have used series turbocharger arrangements. These arrangements dispose two separate turbocharger assemblies on the engine, each having a compressor driven by its own turbine and designed to provide a predetermined portion of the overall required pressure ratio with the output of one turbocharger assembly (first stage) feeding the input of the other turbocharger assembly (second stage). Such arrangements allow each turbocharger assembly to be individually optimized for best performance. Often, the engine may have more than one series turbocharger arrangement adapted to deliver air to some subset of combustion cylinders. Cooling the partially compressed air between the first and second stage further improves efficiency.
Another turbocharger arrangement is the twin compressor turbocharger (“TCT”). U.S. Pat. No. 5,157,924 discloses an example of a turbocharging system that employs the TCT arrangement. An important feature of the TCT arrangement is the mounting of two compressor wheels (first and second stage wheels) on a common rotor shaft. Ducting internal to the device routes the partially compressed air output from the first stage wheel to the inlet of the second stage wheel. TCTs have fewer rotor assemblies on the engine compared with a series turbocharger arrangement and reduce bearing and shaft losses.
Similar with series turbocharger arrangements, TCTs may also have inter-stage cooling. One manner of inter-stage cooling uses a generally annular cooler disposed about the rotor shaft. The overall layout of the air flow passageways directing air into the annular cooler, as well as toward the second stage compressor inlet generally requires a larger package for the rotor housing. Where the mass flow and pressure performance characteristics of the compressor and turbine wheels increase with the square of rotor speed and diameter, thermal heat transfer considerations increase directly (i.e., linearly) with increased mass flow. The mismatch of square turbo performance and linear heat transfer effects makes inter-stage cooled TCTs an essentially non-scalable, turbo-machinery device. Large mass flow and high-pressure applications for TCT technology result in moderate diameter wheels but very large cooler sizes, and, consequently, a very large outside diameter of the rotor housing.
The cooler also generally dictates the axial length of the TCT's compressor section. The overall efficiency of a series turbocharger arrangement is strongly dependent on incurring little or no losses in pressure in the inter-stage ducting. This efficiency requirement drives design of a very low pressure-drop cooler core. The low pressure-drop cooler core in turn requires slowing the airflow down to minimum velocity over the largest possible area (longest axial length, largest outside diameter).
Additionally, measured against traditional inter-stage cooled series turbocharger arrangements, the inter-stage cooled TCT device generally can devote less space and length to smoothly transition the inter-stage airflow, since the air must flow from the first stage compressor outlet, through the cooler, and toward the second stage inlet. The resulting small airflow cross sections, sharp turning radii, and abrupt expansions and contractions significantly decrease the inter-stage cooled TCT's efficiency.
Moreover, balancing the diameter, length, and airflow ducting requirements noted above, generally results in the designer reducing the amount of cooler heat transfer capability of the TCT machine and increasing the interstate cooled temperature fed into the second stage inlet. This increase in interstate temperature again decreases the TCT's efficiency.
The present invention is directed to overcoming one or more of the problems as set forth above.
SUMMARY OF THE INVENTION
In one aspect of the present invention, a supercharger arrangement includes a first rotor assembly, including a first compressor, having a first compressor inlet and a first compressor outlet. A second compressor has a second compressor inlet and a second compressor outlet. A second rotor assembly includes a third compressor, having a third compressor inlet and a third compressor outlet, and a fourth compressor, having a fourth compressor inlet and a fourth compressor outlet. A first inter-stage conduit connects the first compressor outlet and the fourth compressor inlet.
According to another aspect of the invention, a supercharged engine has a combustion chamber. An intake conduit is connected with the combustion chamber. Also, an exhaust conduit connects with the combustion chamber. The supercharged engine includes supercharger arrangement having a first rotor assembly, including a first compressor and a second compressor. A second rotor assembly includes a third compressor and a fourth compressor. An inter-stage conduit connects an outlet of the first compressor with an inlet of the fourth compressor.
According to yet another aspect of the present invention, a method of compressing gas is provided, including compressing a first gas to a first compression stage using a first compressor wheel; further compressing the first gas to a second compression stage using a fourth compressor wheel; compressing a second gas to the first compression stage using a third compressor wheel; and further compressing the second gas to the second compression stage using a second compressor wheel.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic diagram of a supercharger arrangement in accordance with a first embodiment of the invention;
FIG. 2 is a schematic diagram of a supercharger arrangement in accordance with a second embodiment of the invention;
FIG. 3 is a schematic diagram of a supercharger arrangement in accordance with a third embodiment of the invention; and
FIG. 4 is an outline view of part of the supercharger arrangement showing the rectilinear flow configuration of the heat exchanger.
DETAILED DESCRIPTION
As shown in FIG. 1, a supercharging system 100 in accordance with a first embodiment of the present invention includes a first rotor assembly 101 a and a second rotor assembly 101 b. A first stage compressor 102 a (first compressor) is mounted on the first rotor assembly 101 a, and a first stage compressor 102 b (third compressor) is mounted on the second rotor assembly 101 b. A second stage compressor 103 a (second compressor) is mounted on the first rotor assembly 101 a, and a second stage compressor 103 b (fourth compressor) is mounted on the second rotor assembly 101 b. In an embodiment, the first and second stage compressors 102 a-103 b have an axial flow inlet and radial flow outlet. However the present invention will also work with the compressors 102 a-103 b using other flows such as axial inlet and outlet or mixed inlet and radial outlet. The first stage compressor 102 a has an inlet 105 a and an outlet 106 a fluidly connecting with an inlet 107 b of the second stage compressor 103 b. An inter-stage conduit 111 fluidly connects between the first stage compressor outlet 106 a and the second stage compressor inlet 107 b. The second stage compressor 103 b has an outlet 108 b fluidly connecting with a combustion chamber 152 or engine block 150. An intake conduit 155 fluidly connects between the second stage compressor outlet 108 b and the combustion chamber 152. While the engine block 150 is shown defining only two combustion chambers 151, 152, any conventional engine configuration with any number of combustion chambers may be used with the present invention such as a “V”, radial, or in-line configuration.
The first stage compressor 102 b has an inlet 105 b and an outlet 106 b. An inlet 107 a of the second stage compressor 103 a connects with the outlet 106 b of the first stage compressor 102 b. An inter-stage conduit 112 fluidly connects between the first stage compressor outlet 106 b and the second stage compressor inlet 107 a. The second stage compressor 103 a has an outlet 108 a. An intake conduit 153 fluidly connects between the second stage compressor outlet 108 a and a combustion chamber 151.
A heat exchanger or cooler 115 is disposed in the flow path between the compression stages of the supercharger arrangement. Preferably, as shown in FIG. 4 the heat exchanger 115 has one or more cores 118. In an embodiment, the core 118 is rectilinear. As shown in FIG. 1, the conduits 111 and 112 may form part of the heat exchanger 115. Inlet 116 and outlet 117 may be fluidly connected with any coolant source such as water, oil, or air. The heat exchanger may be of any conventional design such as a plate-fin, primary surface recuperator, or tube-fin.
As shown in FIG. 1, the first and second rotor assemblies 101 a and 101 b are driven by respective turbines 104 a and 104 b, each turbine may have any type flow arrangement such as axial inlet and axial outlet, radial inlet and axial outlet, or mixed inlet and outlet. Also, multiple turbines may be used on the rotor assemblies 101 a and 101 b. The first and second rotor assemblies 101 a and 101 b may also be connected to any other drive means such as an electric drive, belt drive connected to an engine shaft, gear drive, or other conventional drive mechanisms. The first turbine 104 a has an intake 109 a connecting to an exhaust conduit 154 for the first combustion chamber 151. Likewise, the second turbine 104 b has an intake 109 b connecting with an exhaust conduit 156 for the second combustion chamber 152. Alternatively, both turbines 104 a and 104 b may be connected with a common manifold (not shown) connected with both the exhaust conduits 154 and 156.
The first rotor assembly 101 a also includes a first rotor shaft 113 a having a first rotor axis X1. The first stage compressor 102 a, second stage compressor 103 a, and first turbine 104 a are coupled to the first rotor shaft 113 a for rotation about the first rotor shaft axis X1. Similarly, the second rotor assembly 101 b includes a second rotor shaft 113 b having a second rotor axis X2. The first stage compressor 102 b, second stage compressor 103 b, and first turbine 104 b are coupled to the second rotor shaft 113 b for rotation about the first rotor shaft axis X2.
FIG. 2 illustrates a supercharger arrangement 200 in accordance with a second embodiment having several features in common with the first embodiment of FIG. 1 and with like parts identified by the same reference numerals. However, one difference between the two embodiments is that, in the second embodiment, the two turbines 104 a and 104 b are disposed on the same side of the supercharger arrangement 200. Furthermore, the inter-stage conduit 120 between the first stage compressor 102 a (first compressor) and the second stage compressor 103 b (fourth compressor) (which is now mounted on a second rotor assembly 122 b) crosses over the inter-stage conduit 121 between the first stage compressor 102 b (third compressor)(which is now mounted on the second rotor assembly 122 b) and the second stage compressor 103 a (second compressor). This cross over occurs preferably before the inter-stage flows pass through the heat exchanger 115 or after these flows exit the heat exchanger 115, thereby permitting the use of a heat exchanger with relatively simple parallel flow paths. However, the cross over may also occur within the heat exchanger 115.
FIG. 3 illustrates a supercharger arrangement 300 in accordance with a third embodiment having several features in common with the first two embodiments of FIGS. 1 and 2 and with like parts identified by the same reference numerals. However, in the embodiment of FIG. 3, each rotor assembly has two compressors of the same stage. That is, the first rotor assembly 130 a has the first stage compressor 131 (first compressor) and the first stage compressor 132 (second compressor). The second rotor assembly 130 b has the second stage compressor 133 (fourth compressor) and the second stage compressor 134 (third compressor). Additionally, as with the embodiment in FIG. 2, the turbines 104 a and 104 b in FIG. 3 are shown disposed on the same side of the supercharger arrangement 300. However, these turbines may also be disposed on opposites of the supercharger arrangement 300.
While not shown in the figures, the supercharger arrangement in accordance with the invention may include devices for controlling the first and second stage boost pressures to optimize the supercharger arrangement's overall performance and protect against negative impacts on the supercharger arrangement. Such control devices as a waste gate, valving, variable nozzle, or variable vanes using various actuator types such as pneumatic, hydraulic, or electronic. Also, each supercharger arrangement may include additional compression stages.
INDUSTRIAL APPLICABILITY
In a vehicle powered by a combustion engine 150, a multi-stage supercharger arrangement 100, 200, 300 in accordance with the invention is used to provide boost pressure. According to one embodiment, the compressor 102 a increases air to pressure P1 and feeds air to compressor 103 b where air pressure increases to P2. Similarly, the compressor 102 b compresses air to P3 and feeds air to compressor 103 a which raises air to pressure P4. The heat exchanger 115 cools the flow of air between compression stages. Using the external heat exchanger allows the supercharger arrangement 100, 200, 300 to be sized separately.
The second stage compressors 103 a and 103 b feed the air compressed to the final boost pressure to the cylinders 151 and 152 of the combustion engine 150. The exhaust gas from the cylinders 151 and 152 is fed to the first and second turbines 104 a, 104 b to drive these turbines and, thereby drive the respective rotor assemblies. In a preferred embodiment, each second stage compressor feeds half the cylinders of the combustion engine 150. Furthermore, each turbine 104 a and 104 b is driven by the flow of exhaust gas from half the cylinders of the combustion engine 150.
Further, the external heat exchanger 115 allows the heat exchanger to have rectilinear flow passageways having large cross-sectional areas. Moreover, primarily because of the more uniform air flow characteristics through the heat exchanger 115, there is improved distribution and more complete use of the heat exchanger's full surface area. Additionally, the supercharger arrangement with a rectilinear heat exchanger can be made into a compact package, because heat exchanger may fit between the rotor assemblies, rather than fully encircling each.
Using the inter-stage conduits 111, 112, 120, and 121, overall mass flow through the rotor assemblies 101 a, 101 b, 122 b, 130 a, and 130 b is balanced. Looking at embodiments of FIGS. 1 and 2, the mass balance is further enhanced by having similar forces on the rotor assemblies 101 a, 101 b, and 122 b so long as the respective turbines 104 a and 104 b receive similar exhaust flows. Even with uneven exhaust flows, exposure to both rotor assemblies 101 a and 101 b or 122 b will result in final output from the second stage compressors 103 a and 103 b being closer than without the inter-stage conduits 111, 112, 120, and 121.
Other aspects, objects and advantages of the present invention can be obtained from a study of the drawings, the disclosure and the appended claims.